Your search keyword '"Robert A Finkelstein"' showing total 7 results

1. The concept of electric charge and the hypothesis of magnetic poles.

Author

Finkelstein, Robert J.

Subjects

MAGNETIC pole, ELECTRIC charge, SPACE probes, NUCLEAR explosions, DEUTERIUM

Abstract

We examine a generic field theory in which the field particle has two couplings. It is of particular interest when these are the electroweak, e , and the hypothetical magnetoweak, g. The new field operators are obtained by replacing the field operators Ψ (x) of the Standard Model or of similar models by Ψ ̃ (x) D q j (m , m ′) where D q j (m , m ′) is an element of the (2 j + 1) -dimensional representation of the SLq(2) algebra, which is also the knot algebra. The new field is assumed to exist in two phases distinguished by two values of q : q e = e q and q g = g q which label the electroweak and magnetoweak phases, respectively. We assume that the observed leptons and quarks are mainly composed of e -preons and are in agreement with the observed charge spectrum of leptons and quarks. It is now proposed that there is also a g -phase where g -leptons and g -quarks are composed of mainly g -preons. It is assumed that the g -charge is very large compared to the e -charge and the mass of the g -charged particle is even larger since the mass of all of these particles is partially determined by the eigenvalues of D ̄ q j (m , m ′) D q j (m , m ′) , a polynomial in q , that multiplies the Higgs mass term and where q g q e = ℏ c e 2 2 ≈ (1 3 7) 2 . Since these values of q g / q e indicate that particles in the g -phase are much more massive, they should be harder to produce or to observe. Since the remote parts of the universe are at increasingly higher temperatures, magnetic poles are perhaps most likely to be found in deep probes of space as well as in high energy accelerators. The section entitled "Introduction" was added only after it was generally realized that the birth of the present universe was probably due to a nuclear explosion. [ABSTRACT FROM AUTHOR]

Published

2019

2. The SLq(2) extension of the standard model.

Author

Finkelstein, Robert J.

Subjects

STANDARD model (Nuclear physics), PARTICLES (Nuclear physics), FERMIONS, SYMMETRY (Physics), KNOT theory, QUANTUM groups

Abstract

The idea that the elementary particles might have the symmetry of knots has had a long history. In any modern formulation of this idea, however, the knot must be quantized. The present review is a summary of a small set of papers that began as an attempt to correlate the properties of quantized knots with empirical properties of the elementary particles. As the ideas behind these papers have developed over a number of years, the model has evolved, and this review is intended to present the model in its current form. The original picture of an elementary fermion as a solitonic knot of field, described by the trefoil representation of SUq(2), has expanded into its present form in which a knotted field is complementary to a composite structure composed of three preons that in turn are described by the fundamental representation of SLq(2). Higher representations of SLq(2) are interpreted as describing composite particles composed of three or more preons bound by a knotted field. This preon model unexpectedly agrees in important detail with the Harari-Shupe model. There is an associated Lagrangian dynamics capable in principle of describing the interactions and masses of the particles generated by the model. [ABSTRACT FROM AUTHOR]

Published

2015

3. The preon sector of the SLq(2) model and the binding problem.

Author

Finkelstein, Robert J.

Subjects

QUANTUM field theory, LEPTONS (Nuclear physics), NEUTRINOS, QUARKS, COMPOSITE particles (Nuclear particles), PARTICLES (Nuclear physics), PARAMETER estimation

Abstract

There are suggestive experimental indications that the leptons, neutrinos, and quarks might be composite and that their structure is described by the quantum group SLq(2). Since the hypothetical preons must be very heavy relative to the masses of the leptons, neutrinos, and quarks, there must be a very strong binding field to permit these composite particles to form. Unfortunately there are no experiments direct enough to establish the order of magnitude needed to make the SLq(2) Lagrangian dynamics quantitative. It is possible, however, to parametrize the preon masses and interactions that would be necessary to stabilize the three particle composite representing the leptons, neutrinos, and quarks. In this note we examine possible parametrizations of the masses and the interactions of these hypothetical structures. We also note an alternative view of SLq(2) preons. [ABSTRACT FROM AUTHOR]

Published

2014

4. KNOTS AND PREONS.

Author

FINKELSTEIN, ROBERT J.

Subjects

SOLITONS, QUANTUM theory, ALGEBRA, BOSONS, FERMIONS, PARTICLES (Nuclear physics)

Abstract

It is shown that the four quantum trefoil solitons that are described by the irreducible representations ${\mathcal D}^{3/2}_{mm^\prime}$ of the quantum algebra SLq(2) [and that may be identified with the four families of elementary fermions (e, μ, τ; νeνμντ;d, s, b; u, c, t)] may be built out of three preons, chosen from two charged preons with charges (1/3, -1/3) and two neutral preons. These preons are fermions and are described by the ${\mathcal D}^{1/2}_{mm^\prime}$ representation of SLq(2). There are also four bosonic preons described by the ${\mathcal D}^1_{mm^\prime}$ and ${\mathcal D}^0_{00}$ representations of SLq(2). The knotted standard theory may be replicated at the preon level and the conjectured particles are in principle indirectly observable. [ABSTRACT FROM AUTHOR]

Published

2009

5. THE ELEMENTARY PARTICLES AS QUANTUM KNOTS IN ELECTROWEAK THEORY.

Author

Finkelstein, Robert J.

Subjects

PARTICLES (Nuclear physics), INTERACTING boson-fermion models, LEPTONS (Nuclear physics), QUANTUM statistics, ISOBARIC spin

Abstract

We explore a knot model of the elementary particles that is compatible with electroweak physics. The knots are quantized and their kinematic states are labeled by $D^j_{mm^\prime}$, irreducible representations of SUq(2), where j = N/2, m = w/2, m′ = (r+1)/2 and (N, w, r) designate respectively the number of crossings, the writhe, and the rotation of the knot. The knot quantum numbers (N, w, r) are related to the standard isotopic spin quantum numbers (t, t3, t0) by (t = N/6, t3 = -w/6, t0 = -(r+1)/6), where t0 is the hypercharge. In this model the elementary fermions are low lying states of the quantum trefoil (N = 3) and the gauge bosons are ditrefoils (N = 6). The fermionic knots interact by the emission and absorption of bosonic knots. [ABSTRACT FROM AUTHOR]

Published

2007

6. MASSES AND INTERACTIONS OF q-FERMIONIC KNOTS.

Author

FINKELSTEIN, ROBERT J. and CADAVID, A. C.

Subjects

FERMIONS, PARTICLES (Nuclear physics), LEPTONS (Nuclear physics), QUARKS, WEAK interactions (Nuclear physics), NEUTRINOS

Abstract

The q-electroweak theory suggests a description of elementary particles as solitons labeled by the irreducible representations of SUq(2). Since knots may also be labeled by the irreducible representations of SUq(2), we study a model of elementary particles based on a one-to-one correspondence between the four families of fermions (leptons, neutrinos, (-1/3) quarks, (2/3) quarks) and the four simplest knots (trefoils). In this model the three particles of each family are identified with the ground and first two excited states of their common trefoil. Guided by the standard electroweak theory, we calculate conditions restricting the masses of the fermions and the interactions between them. In its present form the model predicts a fourth generation of fermions as well as a neutrino spectrum. The same model with q ≅ 1 is compatible with the Kobayashi–Maskawa matrix. Depending on the test of these predictions, the model may be refined. [ABSTRACT FROM AUTHOR]

Published

2006

7. A KNOT MODEL SUGGESTED BY THE STANDARD ELECTROWEAK THEORY.

Author

FINKELSTEIN, ROBERT J.

Subjects

ELECTROWEAK interactions, ELECTROMAGNETIC interactions, SOLITONS, GEOMETRIC connections, MATHEMATICS, ALGEBRA

Abstract

We attempt to go beyond the standard electroweak theory by replacing SU(2) with its q-deformation: SUq(2). This step introduces new degrees of freedom that we interpret as indicative of nonlocality and as a possible basis for a solitonic model of the elementary particles. The solitons are conjectured to be knotted flux tubes labeled by the irreducible representations of SUq(2), an algebra which is not only closely related to the standard theory but also plays an underlying role in the description of knots. Each of the four families of elementary fermions is conjectured to be represented by one of the four possible trefoils. The three individual fermions belonging to any family are then assumed to occupy the three lowest states in the excitation spectrum of the trefoil for that family. One finds a not unreasonable variation of q among the lepton and quark families. The model in its present form predicts a fourth generation of fermions as well as a neutrino mass spectrum. The model may be refined depending on whether or not the fourth generation is found. [ABSTRACT FROM AUTHOR]

Published

2005